1364186 九、發明說明: 【發明所屬之技術領域】 本發明係關於一種用以中繼一資料訊號之裝置、傳輸方法及電 腦可讀取記錄媒體。更具體而言,本發明係關於一種用以於多重 躍進中繼網路中繼一資料訊號之裝置、傳輪方法及電腦可讀取記 錄媒體。 【先前技術】 在IEEE 802.16標準中所採用之混合自動重傳請求(hybrid automatic request ’以下簡稱H ARQ )技術係為一種先進的資料重傳 策略,此種技術能夠直接於實體層而非於媒體存取控制(MAC) 層及/或更高層上進行需要之資料重傳《由於HARQ技術能夠於不 涉及更高層之機制情況下達成資料重傳,因而由資料重傳所致之 延遲大幅降低。然而’ HARQ技術於多重躍進中繼網路中仍存在 某些缺陷,這些缺陷將被定義於IEEE 802,16j標準中。由於HARQ 通道可藉由二方法(點對點(end-to-end ) HARQ機制與逐跳式 (hop-by-hop) HARQ機制)加以設置,因而主要從這二方法之觀 點描述HARQ之缺陷。 請參見第1圖,其例示由一多重躍進中繼(multi-hop relay,以 下簡稱MR)系統1使用一習知點對點HARQ機制中繼一資料訊 號。MR系統1包含一行動台(mobile station,以下簡稱ms )、二 中繼台(relay station,以下簡稱RS,即RS1及RS2 )、及一基地 台(base station,以下簡稱BS) » BS欲傳輸資料訊號至MS。於 第1圖中’垂直轴係指示時間,「Data*」係指示於傳輸過程中遭雜 1364186 ' 訊破壞之資料訊说’而「Data」則指示成功得到傳輸且未於傳輸 過程中遭雜訊破壞之資料訊號。可以理解的是,各該RS (即RS1 及RS2)應僅將被成功接收到/解碼出之資料訊號,以點對點HARQ 機制中繼至其下一站台。若RS接收到一被錯誤解碼之資料訊號, 則傳送一反確認(NACK)至原始發送方,以指示請求重傳《換言 之’各該RS應將所有所接收之確認(ACK) /反確認(NACK)中 繼至其前一站台。此外’僅傳輸之目的站台可發起一 ACK。但這 ^ 將導致資料傳送延遲過大’同時會降低整個系統1之效能。點對 點HARQ通道亦存在其他緊要之問題。第一,於集中排程之mr 系統令’若中繼路徑之任一鏈路上出現錯誤,將不能充分利用沿 該中繼路徑之多個鏈路之預留頻寬;第二,若HARQ頻寬之分配 係以需求為導向’則其肯定會於MS/RS與BS間引起諸多往返延 時後才能成功地得到接收/解碼;第三,點對點HARQ並不適用於 分散式排程之MR系統。 請參見第2圖’其例示一使用一習知逐跳式機制中繼一資料訊 # 號之MR系統2°MR系統2亦包含一 MS、二RS(即RS1及RS2)、 及一 BS。於第2圖中,垂直軸係指示時間,「Data*」係指示於傳 輸過程中遭雜訊破壞之資料訊號,而「Dataj則指示成功得到傳 輸之資料訊號。在使用逐跳式HARQ機制時,各該RS (即RS1 及RS2)不應中繼錯誤解碼之資料訊號至其下一站台,除非該資 料訊號得到成功解碼。此外,各該RS不應中繼所接收ack/nack 指示至其前一站台。逐跳式HARQ機制存在二主要缺陷。第一, 在中繼系統2採用集中式排程方法時,若沿中繼路徑於任一鏈路 1364186 •-上出現錯誤,皆將不能充分利用BS與MS間沿該中繼路徑之多個 鏈路之預留頻寬。第二’若HARQ頻寬之分配係以需求為導向, 貝1J其將在於MS/RS與BS間之中繼路徑引起諸多往返延時。 因此’如何改善多重躍進中繼系統中HARQ之效能仍係業界所 要努力達成之目標。 【發明内容】 I 本發明之主要目的係提供一種用以於一多重躍進中繼網路中繼 一資料訊號之裝置。該裝置包含一儲存模組、一接收模組以及一 傳輪模組。該儲存模組用以儲存該多重躍進中繼網路之一資訊, 其中該資訊用以指示該多重躍進中繼網路之一資源配置。該接收 模組用以接收該資料訊號。該傳輸模組用以因應該資料訊號而根 據該資訊傳輸該資料訊號及一第一反應訊號,其中該第一反應訊 號係關於該資料訊號之一正確性。 本發明之另一目的係提供一種用以於一多重躍進甲繼網路中繼 • 一資料訊號之傳輸方法。該傳輸方法包含下列步驟:接收該資料 訊號;因應該接收步驟,根據該多重躍進中繼網路之一資訊,傳 輸該資料訊號,其中該資訊用以指示該多重躍進中繼網路之一資 源配置;以及因應該接收步驟,根據該資訊,傳輸—第一反廡訊 號,其中該第一反應訊號係關於該資料訊號之一正確性。 本發明之又一目的係提供一種電腦可讀取記錄媒體,用以儲存 一應用程式,該應用程式用以使一裝置執行一種用以於一多重躍 進中繼網路中繼一資料訊號之傳輸方法。該傳輪方法包含下列步 驟··令該裝置接收該資料訊號;令該裝置因應該接收步驟,根據 1364186 該多重躍進中繼網路之一資訊,傳輸該資料訊號,其中該資訊用 以指示該多重躍進中繼網路之一資源配置;以及令該裝置因應該 接收步驟,根據該資訊傳輸一第一反應訊號,其中該第一反應訊 號係關於該資料訊號之一正確性。 本發明提供一種用以於一多重躍進中繼網路中繼一資料訊號之 新方法。於HARQ之架構中,無論資料訊號是否於傳輸過程中遭 雜訊破壞,中繼台皆中繼該資料訊號至下一站台。此將有效利用 多個鏈路之預排程頻寬,以改良多重躍進中繼網路中整個中繼系 統之效能。 在參閱圖式及隨後描述之實施方式後,所屬技術領域具有通常 知識者便可瞭解本發明之目的,以及本發明之技術手段及實施態 樣。 【實施方式】 本發明提供一種用以於一多重躍進中繼網路中繼一資料訊號之 裝置、傳輸方法及電腦可讀取記錄媒體。在下述各實施例中,係 使用基於IEEE 802.16j標準之多重躍進中繼網路。然而,本發明 之範疇並非僅限於基於IEEE 802.16j標準之應用。基於IEEE 802.16j標準之多重躍進中繼網路之中繼運作已為熟習此項技術者 所習知,因而不再加以贅述。多重躍進中繼網路具有二種運作: 下行鏈路運作與上行鏈路運作。在本發明中,僅闡述多重躍進中 繼網路之下行鏈路運作。此意味著將僅闡述自一基地台(BS)至 一行動台(MS)之中繼運作。 第3圖顯示本發明之一第一實施例,其係為一用以於一多重躍 1364186 進中繼網路中將一資料訊號32自一 BS中繼至一 MS之裝置3。裝 置3可於該多重躍進中繼網路中作為一中繼台(RS)。裝置3包含 一儲存模組31、一接收模組33、一傳輸模組35、以及一判斷模組 37。儲存模組31用以儲存該多重躍進中繼網路之一資訊34,其中 資訊34用以指示該多重躍進中繼網路之一資源配置。 接收模組33用以接收資料訊號32。於接收模組33接收資料訊 號32後,儲存模組31將之儲存。然後,傳輸模組35用以自儲存 模組31擷取資料訊號32,將資料訊號32傳輸至其下一站台(參 見下文),並因應資料訊號32,根據資訊34將一第一反應訊號36 傳輸至其前一站台(參見下文),其中第一反應訊號36係關於資 料訊號32之一正確性。更具體而言,資料訊號32分別發送至傳 輸模組35及判斷模組37。判斷模組37用以判斷資料訊號32是否 正確。即,判斷模組37用以判斷資料訊號32於傳輸過程中是否 遭雜訊破壞。若資料訊號32正確,則判斷模組37更用以產生一 確認訊號作為第一反應訊號36,以由傳輸模組35傳輸至其前一站 台(.參見下文)。而若判斷模組37判斷出該資料訊號錯誤,則傳 輸一反確認訊號作為第一反應訊號36,以由傳輸模組35傳輸至其 前一站台(參見下文)。 傳輸模組35係因應資料訊號32,根據資訊34傳輸上述資料訊 號32及上述第一反應訊號36。詳言之,資訊34記錄裝置3、BS 與MS間之關係。若於多重躍進中繼網路中存在其他中繼台,則 資訊34亦記錄其他中繼台與該裝置、BS、以及MS間之關係。藉 此,裝置3之傳輸模組35即可藉由資訊34得知其下一站台(例 1364186 如RS/MS )及/或前一站台(例如) 此外,接收模組33更用以接收飞傳輪至BS之第二反應訊號。 此係於資料訊號32最終到達MS時進行,ms係傳輸該第二反應 訊號以}曰示接收到寊料訊號32。傳輪模、纟且%更用以根據資訊34 傳輸第二反應訊號。更具體而言,MS所接收之資料訊號32既可 能正確亦可能錯誤。若其正確,則第二反應訊號係為一確認訊號。 反之,若MS所接收之資料訊號32錯誤,則第二反應訊號係為一 反確認訊號。此意味著裝置3可於該多重躍進中繼網路中繼一瑞 認訊號及反確認訊號。 如上文所述,裝置3可為一多重躍進t繼系統中之一中繼台。 請參見圖4中之具體實例,其顯示一多重躍進中繼系統4中一資 料訊號之下行鏈路傳輸。多重躍進中繼系統4包含一 MS、二RS (RS1及RS2)、及一 BS,其中各該RS1及RS2即係本實施例之 裝置3。此外,在第4圖中’垂直軸指示時間,「Data*」係指示於 傳輸過程中遭雜訊破壞之資料訊號’而「Data」則指示成功得到傳 輸之資料訊號。 . 於多重躍進中繼系統4中,各該RS1及RS2 (沿自BS至MS之 路由路徑)應暫存由其前一站台發送之資料訊號,且無論該資料 訊號是否正確’都將該資料訊號中繼至其下一站台,並因應接收 到該資料訊號而向其前一站台報告一第一反應訊號,其中該第一 反應訊號可係為一確認訊號(ACK)或一反確認訊號(NACK)。 此外,各該RS1及RS2應將由MS初始發送之一第二反應訊號中 繼至其後一站台,其中該第二反應訊號可係為一 ACK或一 NACK° 1364186 根據以上配置,本發明提供一種用以中繼一資料訊號之裝置, 無論此資料訊號之正確性如何。此可利用多個鏈路之預留頻寬來 改良多重躍進中繼網路中下行鏈路中繼系統之效能。 第5A圖及第5B圖中顯示本發明之一第二實施例,其係為一種 用以於一多重躍進中繼網路中繼一資料訊號之傳輸方法之流程 圖,其中該多重躍進中繼網路包含複數個中繼台。首先,執行步 驟500以接收資料訊號。因應該接收步驟500,執行步驟501,以 根據該多重躍進中繼網路之一資訊,傳輸該資料訊號,其中該資 訊用以指示該等中繼台間之關係。 然後,執行步驟502,以接收一欲傳輸至一基地台之第二反應訊 號,其中該第二反應訊號可係為一確認訊號或一反確認訊號,視 其該多重躍進中繼網路中一行動台所接收資料訊號之正確性而 定。然後,執行步驟503,以根據該資訊來傳輸第二反應訊號。 請參見第5B圖,隨後執行步驟504,以判斷在步驟500中所接收 之資料訊號是否正確。若正確,則執行步驟505,以產生一確認訊 號作為一第一反應訊號。接著執行步驟506,因應接收步,500, 以根據該資訊將該第一反應訊號傳輸至該多重躍進中繼網路中之 一基地台。 若步驟504之判斷結果為否,則執行步驟507,以產生一反確認 訊號作為第一反應訊號,並隨後執行步驟508,因應接收步驟500, 根據該資訊來傳輸第一反應訊號。1364186 IX. Description of the Invention: [Technical Field] The present invention relates to an apparatus for relaying a data signal, a transmission method, and a computer readable recording medium. More specifically, the present invention relates to an apparatus for relaying a data signal to a multi-hop relay network, a method of transmitting a wheel, and a computer readable recording medium. [Previous Technology] Hybrid automatic request (HARQ) technology adopted in the IEEE 802.16 standard is an advanced data retransmission strategy, which can be directly applied to the physical layer instead of the media. Re-transmission of required data at the Access Control (MAC) layer and/or higher level "Because HARQ technology can achieve data retransmission without involving higher-level mechanisms, the delay caused by data retransmission is greatly reduced. However, HARQ technology still has certain defects in the multi-jump relay network, and these defects will be defined in the IEEE 802, 16j standard. Since the HARQ channel can be set by two methods (end-to-end HARQ mechanism and hop-by-hop HARQ mechanism), the defect of HARQ is mainly described from the viewpoint of these two methods. Referring to Fig. 1, it is exemplified that a multi-hop relay (hereinafter referred to as MR) system 1 relays a data signal using a conventional point-to-point HARQ mechanism. The MR system 1 includes a mobile station (hereinafter referred to as ms), a relay station (hereinafter referred to as RS, ie, RS1 and RS2), and a base station (hereinafter referred to as BS). Information signal to MS. In Figure 1, the 'vertical axis indicates time, 'Data*' indicates that the data was disturbed during the transmission, and the data was successfully transmitted and not transmitted during the transmission. Information on the destruction of the information. It can be understood that each RS (ie, RS1 and RS2) should only relay the successfully received/decoded data signal to its next station in a point-to-point HARQ mechanism. If the RS receives an erroneously decoded data signal, it transmits a reverse acknowledgment (NACK) to the original sender to indicate that the request is retransmitted. In other words, each of the RSs shall acknowledge all received acknowledgments (ACKs)/reverse acknowledgments ( NACK) relays to its previous station. In addition, the destination station that transmits only can initiate an ACK. However, this will result in excessive data transfer delays' while reducing the performance of the entire system 1. Point-to-point HARQ channels also have other critical issues. First, in the centralized scheduling mr system, 'if there is an error on any link of the relay path, the reserved bandwidth of multiple links along the relay path will not be fully utilized; second, if the HARQ bandwidth is The allocation is demand-oriented', which will definitely result in many round-trip delays between the MS/RS and the BS before it can be successfully received/decoded. Third, the point-to-point HARQ is not suitable for the distributed scheduling MR system. Referring to Fig. 2, an exemplary MR system for relaying a data message using a conventional hop-by-hop mechanism also includes an MS, two RSs (i.e., RS1 and RS2), and a BS. In Figure 2, the vertical axis indicates the time, "Data*" indicates the data signal that was corrupted during the transmission, and "Dataj indicates the data signal that was successfully transmitted. When using the hop-by-hop HARQ mechanism Each RS (ie, RS1 and RS2) shall not relay the error decoded data signal to its next station unless the data signal is successfully decoded. In addition, each RS shall not relay the received ack/nack indication to it. The previous station. The hop-by-hop HARQ mechanism has two major drawbacks. First, when the relay system 2 adopts the centralized scheduling method, if an error occurs on any link 1364186 on the relay path, it will not be fully utilized. The reserved bandwidth of the multiple links along the relay path between the BS and the MS. The second 'if the allocation of the HARQ bandwidth is demand-oriented, the shell 1J will be the relay path between the MS/RS and the BS. It causes a lot of round trip delays. Therefore, 'how to improve the performance of HARQ in the multi-hop relay system is still the goal that the industry has to work hard to achieve. The first objective of the present invention is to provide a multi-hop relay network. Road relay one The device includes a storage module, a receiving module and a transmission module. The storage module is configured to store information of the multiple-hop relay network, wherein the information is used to indicate the multiple a resource configuration of the hopping relay network for receiving the data signal. The transmission module is configured to transmit the data signal and a first response signal according to the information according to the information signal, wherein the first The response signal is related to the correctness of the data signal. Another object of the present invention is to provide a method for transmitting a data signal in a multi-jump network relay. The transmission method comprises the following steps: receiving The data signal; in response to the receiving step, transmitting the data signal according to one of the multiple leap relay networks, wherein the information is used to indicate resource configuration of the multi-hop relay network; and According to the information, the first response signal is transmitted, wherein the first response signal is correct for one of the data signals. A computer readable recording medium for storing an application for causing a device to perform a transmission method for relaying a data signal to a multi-hop relay network. The method includes The following steps: • causing the device to receive the data signal; causing the device to transmit the data signal according to one of the multiple jump relay networks of 1364186, wherein the information is used to indicate the multiple leap relay network And configuring the device to transmit a first response signal according to the information, wherein the first response signal is correct for one of the data signals. The present invention provides a method for correcting one of the data signals. A new method of re-entering the relay network to relay a data signal. In the HARQ architecture, the relay station relays the data signal to the next station regardless of whether the data signal is corrupted during transmission. This will effectively utilize the pre-scheduling bandwidth of multiple links to improve the performance of the entire trunk system in a multi-hop relay network. The objects of the present invention, as well as the technical means and implementations of the present invention, will be apparent to those of ordinary skill in the art. [Embodiment] The present invention provides a device, a transmission method, and a computer readable recording medium for relaying a data signal to a multi-hop relay network. In the following embodiments, a multi-hop relay network based on the IEEE 802.16j standard is used. However, the scope of the present invention is not limited to applications based on the IEEE 802.16j standard. The relaying operation of the multi-hop relay network based on the IEEE 802.16j standard has been known to those skilled in the art and will not be described again. The multi-hop relay network has two functions: downlink operation and uplink operation. In the present invention, only the operation of the downlink under the multi-hop relay network is explained. This means that only relay operations from a base station (BS) to a mobile station (MS) will be described. Figure 3 shows a first embodiment of the present invention, which is a device 3 for relaying a data signal 32 from a BS to an MS in a multi-hop 1364186 trunk network. The device 3 can function as a relay station (RS) in the multi-hop relay network. The device 3 includes a storage module 31, a receiving module 33, a transmission module 35, and a judging module 37. The storage module 31 is configured to store one of the multiple leap relay network information 34, wherein the information 34 is used to indicate resource configuration of the multi-hop relay network. The receiving module 33 is configured to receive the data signal 32. After the receiving module 33 receives the data signal 32, the storage module 31 stores it. Then, the transmission module 35 is configured to retrieve the data signal 32 from the storage module 31, transmit the data signal 32 to its next station (see below), and respond to the data signal 32 to generate a first response signal 36 according to the information 34. It is transmitted to its previous station (see below), where the first response signal 36 is correct for one of the data signals 32. More specifically, the data signal 32 is sent to the transmission module 35 and the determination module 37, respectively. The determining module 37 is configured to determine whether the data signal 32 is correct. That is, the determining module 37 is configured to determine whether the data signal 32 is corrupted by noise during transmission. If the data signal 32 is correct, the determining module 37 is further configured to generate a confirmation signal as the first response signal 36 for transmission by the transmission module 35 to its previous station (see below). If the judging module 37 judges that the data signal is wrong, a deassertion signal is transmitted as the first response signal 36 for transmission by the transmission module 35 to its previous station (see below). The transmission module 35 transmits the data signal 32 and the first response signal 36 according to the information 34 in response to the data signal 32. In detail, the information 34 records the relationship between the device 3, the BS and the MS. If there are other repeaters in the multi-hop relay network, the information 34 also records the relationship between the other repeaters and the device, the BS, and the MS. Thereby, the transmission module 35 of the device 3 can learn the next station (for example, 1364186 such as RS/MS) and/or the previous station (for example) by using the information 34. In addition, the receiving module 33 is further used to receive the fly. Pass the second reaction signal to BS. This is done when the data signal 32 finally arrives at the MS, and the ms transmits the second response signal to indicate that the received signal 32 is received. The pass mode, 纟 and % are used to transmit the second response signal according to the information 34. More specifically, the data signal 32 received by the MS may be correct or incorrect. If it is correct, the second response signal is a confirmation signal. Conversely, if the data signal 32 received by the MS is incorrect, the second response signal is a reverse acknowledgement signal. This means that the device 3 can relay a relay signal and a counter-acknowledgment signal on the multiple-hop relay network. As described above, the device 3 can be a multi-hop relay t relay system. Referring to the specific example in FIG. 4, it shows a downlink transmission of a data signal in a multi-hop relay system 4. The multi-hop relay system 4 includes an MS, two RSs (RS1 and RS2), and a BS, wherein each of the RS1 and RS2 is the apparatus 3 of the embodiment. In addition, in Fig. 4, the 'vertical axis indicates the time, "Data*" indicates the data signal destroyed by the noise during the transmission, and "Data" indicates that the transmitted data signal was successfully transmitted. In the multi-hop relay system 4, each of the RS1 and RS2 (along the routing path from the BS to the MS) should temporarily store the data signal sent by the previous station, and whether the data signal is correct or not, the data is The signal is relayed to its next station, and a first response signal is reported to the previous station in response to receiving the data signal, wherein the first response signal can be an acknowledgement signal (ACK) or a reverse acknowledgement signal ( NACK). In addition, each of the RS1 and the RS2 should relay a second response signal originally sent by the MS to a subsequent station, wherein the second response signal can be an ACK or a NACK. 1364186. According to the above configuration, the present invention provides a A device used to relay a data signal, regardless of the correctness of the data signal. This can utilize the reserved bandwidth of multiple links to improve the performance of the downlink relay system in a multi-hop relay network. A second embodiment of the present invention is shown in FIG. 5A and FIG. 5B, which is a flow chart of a method for transmitting a data signal in a multi-hop relay network, wherein the multiple leap forward The network includes a plurality of repeaters. First, step 500 is performed to receive the data signal. In response to step 500, step 501 is performed to transmit the data signal according to one of the multiple leap relay networks, wherein the information is used to indicate the relationship between the relay stations. Then, step 502 is performed to receive a second response signal to be transmitted to a base station, where the second response signal can be a confirmation signal or a reverse confirmation signal, depending on the multi-hop relay network. The correctness of the information signal received by the mobile station. Then, step 503 is performed to transmit the second response signal according to the information. Referring to Figure 5B, step 504 is then performed to determine if the data signal received in step 500 is correct. If yes, step 505 is executed to generate a confirmation signal as a first response signal. Then, step 506 is executed, in response to receiving step 500, to transmit the first reaction signal to one of the multiple leap relay networks according to the information. If the result of the determination in step 504 is no, step 507 is executed to generate a reverse acknowledgement signal as the first response signal, and then step 508 is executed. In response to receiving step 500, the first response signal is transmitted according to the information.
應注意,步驟505,506可先於步驟502,503執行。類似地, 步驟507,508可先於步驟502,503執行。該執行順序係依據BS 11 1364186 ' t-排程演算法。除上述步驟之外,第二實施例亦能夠執行在第 一實施例中所述之所有功能及操作。 各該上述方法可使用一電腦可讀取記錄媒體來儲存一用以執行 上述步驟之電腦程式。該電腦可讀取記錄媒體可料軟磁碟、= 磁碟、光碟、快閃碟、磁帶、可自-網路存取之資料庫、或者熟 s此項技術者可輕易思及之具有相同功能之儲存媒體。 根據上文說明可知,本發明提供一種中繼—資料訊號之裝置、 # 傳輸方法及其電腦可讀取記錄媒體,無論資料訊號之正確性如 何,本發明皆將該資料訊號自其前—站台中繼至其下一站台。此 將有效利用預留頻寬來改良多重躍進中繼網路之中繼系統之效 月b。本發明可用於多重躍進中繼網路,例如基於IEEE 8〇2丨句之 多重躍進中繼網路。 上述之實施例僅用來例舉本發明之實施態樣,以及闡釋本發明 之技術特徵,並非用來限制本發明之範疇。任何熟悉此技術者可 輕易完成之改變或均等性之安排均屬於本發明所主張之範圍,本 • 發明之權利範圍應以申請專利輯®為準。 【圖式簡單說明】 第1圖係為一由一 MR系統使用—習知點對點HARQ機制中繼 一資料訊號之示意圖; 第2圖係為一由一 MR系統使用—習知逐跳式HARQ機制中繼 一資料訊號之示意圖; 第3圖係為本發明第一實施例之—示意圖; 第4圖係為採用本發明第一實施例之裝置之下行鏈路中繼系統 (S 7 12 1364186 之一示意圖; 第5A圖係為本發明第二實施例之一局部流程圖;以及 第5B圖係為本發明第二實施例之另一局部流程圖。 【主要元件符號說明】 RS1 :中繼台 BS :基地台 NACK :反確認訊號 MS :行動台 RS2 :中繼台 ACK :確認訊號 Data* :遭雜訊破壞之資料訊號It should be noted that steps 505, 506 may be performed prior to steps 502, 503. Similarly, steps 507, 508 can be performed prior to steps 502, 503. The execution sequence is based on the BS 11 1364186 't-scheduling algorithm. In addition to the above steps, the second embodiment is capable of performing all of the functions and operations described in the first embodiment. Each of the above methods can use a computer readable recording medium to store a computer program for performing the above steps. The computer can read the recording media, such as floppy disk, = disk, CD, flash disk, tape, database accessible from the Internet, or familiar with the technology can easily think of the same function Storage media. According to the above description, the present invention provides a relay-data signal device, a #transmission method, and a computer-readable recording medium. The present invention transmits the data signal from the front station regardless of the correctness of the data signal. The station relays to its next station. This will effectively utilize the reserved bandwidth to improve the effectiveness of the relay system of the multi-hop relay network. The present invention can be used in a multi-hop relay network, such as a multi-hop relay network based on IEEE 8〇2 丨. The embodiments described above are only intended to illustrate the embodiments of the invention, and to illustrate the technical features of the invention, and are not intended to limit the scope of the invention. Any changes or equivalences that can be easily accomplished by those skilled in the art are within the scope of the invention, and the scope of the invention should be based on the patent application. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram of a data transmission using a conventional point-to-point HARQ mechanism used by an MR system; Figure 2 is a use of an MR system - a conventional hop-by-hop HARQ mechanism FIG. 3 is a schematic diagram of a first embodiment of the present invention; FIG. 4 is a downlink relay system of the apparatus according to the first embodiment of the present invention (S 7 12 1364186) Figure 5A is a partial flow chart of a second embodiment of the present invention; and Figure 5B is another partial flow chart of the second embodiment of the present invention. [Explanation of main component symbols] RS1: Repeater BS: base station NACK: reverse acknowledgement signal MS: mobile station RS2: relay station ACK: acknowledge signal Data*: data signal corrupted by noise
Data :成功得到傳輸且未於傳輸過程中遭雜訊破壞之資料訊號 31 :儲存模組 33 :接收模組 35 :傳輸模組 37 ··判斷模組 3 :裝置 32 :資料訊號 34 :資訊 36:第一反應訊號 13Data: Data signal 31 successfully transmitted and not corrupted during transmission: storage module 33: receiving module 35: transmission module 37 · judging module 3: device 32: data signal 34: information 36 : First response signal 13